Boundary feedback stabilization and Riesz basis property of a 1-d first order hyperbolic linear system with L∞-coefficients

Boumediène Chentouf; Jun Min Wang

doi:10.1016/j.jde.2008.08.010

Boundary feedback stabilization and Riesz basis property of a 1-d first order hyperbolic linear system with L^∞-coefficients

Boumediène Chentouf^*, Jun Min Wang

^*المؤلف المقابل لهذا العمل

Mathematics

نتاج البحث: المساهمة في مجلة › Article › مراجعة النظراء

15 اقتباسات (Scopus)

ملخص

This paper deals with the boundary feedback stabilization problem of a wide class of linear first order hyperbolic systems with non-smooth coefficients. We propose static boundary inputs (actuators) which lead us to a closed loop system with non-smooth coefficients and non-homogeneous boundary conditions. Then, we prove the exponential stability of the closed loop system under suitable conditions on the coefficients and the feedback gains. The key idea of the proof is to combine the regularization techniques with the characteristics method. Furthermore, by the spectral analysis method, it is also shown that the closed loop system has a sequence of generalized eigenfunctions, which form a Riesz basis for the state space, and hence the spectrum-determined growth condition is deduced.

اللغة الأصلية	English
الصفحات (من إلى)	1119-1138
عدد الصفحات	20
دورية	Journal of Differential Equations
مستوى الصوت	246
رقم الإصدار	3
المعرِّفات الرقمية للأشياء	https://doi.org/10.1016/j.jde.2008.08.010
حالة النشر	Published - فبراير 1 2009

ASJC Scopus subject areas

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الوصول إلى المستند

10.1016/j.jde.2008.08.010

الملفات والروابط الأخرى

قم بذكر هذا

Boundary feedback stabilization and Riesz basis property of a 1-d first order hyperbolic linear system with L^∞-coefficients. / Chentouf, Boumediène; Wang, Jun Min.
في: Journal of Differential Equations, المجلد 246, رقم 3, ٠١.٠٢.٢٠٠٩, صفحة 1119-1138.

نتاج البحث: المساهمة في مجلة › Article › مراجعة النظراء

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title = "Boundary feedback stabilization and Riesz basis property of a 1-d first order hyperbolic linear system with L∞-coefficients",

abstract = "This paper deals with the boundary feedback stabilization problem of a wide class of linear first order hyperbolic systems with non-smooth coefficients. We propose static boundary inputs (actuators) which lead us to a closed loop system with non-smooth coefficients and non-homogeneous boundary conditions. Then, we prove the exponential stability of the closed loop system under suitable conditions on the coefficients and the feedback gains. The key idea of the proof is to combine the regularization techniques with the characteristics method. Furthermore, by the spectral analysis method, it is also shown that the closed loop system has a sequence of generalized eigenfunctions, which form a Riesz basis for the state space, and hence the spectrum-determined growth condition is deduced.",

keywords = "C-semigroup, First order hyperbolic linear system, L-coefficients, Regularization method, Riesz basis, Stability",

author = "Boumedi{\`e}ne Chentouf and Wang, {Jun Min}",

note = "Funding Information: The authors are grateful to the anonymous referee for his/her constructive criticism and valuable suggestions and for having mentioned to them Ref. [18]. The first author also acknowledges the support of Sultan Qaboos University. Funding Information: E-mail addresses: chentouf@squ.edu.om (B. Chentouf), wangjc@graduate.hku.hk (J.-M. Wang). 1 The research of the author was supported by Sultan Qaboos University. 2 The research of the author was supported by the National Natural Science Foundation of China and the Program for New Century Excellent Talents in University of China.",

year = "2009",

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doi = "10.1016/j.jde.2008.08.010",

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AU - Chentouf, Boumediène

AU - Wang, Jun Min

N1 - Funding Information: The authors are grateful to the anonymous referee for his/her constructive criticism and valuable suggestions and for having mentioned to them Ref. [18]. The first author also acknowledges the support of Sultan Qaboos University. Funding Information: E-mail addresses: chentouf@squ.edu.om (B. Chentouf), wangjc@graduate.hku.hk (J.-M. Wang). 1 The research of the author was supported by Sultan Qaboos University. 2 The research of the author was supported by the National Natural Science Foundation of China and the Program for New Century Excellent Talents in University of China.

PY - 2009/2/1

Y1 - 2009/2/1

N2 - This paper deals with the boundary feedback stabilization problem of a wide class of linear first order hyperbolic systems with non-smooth coefficients. We propose static boundary inputs (actuators) which lead us to a closed loop system with non-smooth coefficients and non-homogeneous boundary conditions. Then, we prove the exponential stability of the closed loop system under suitable conditions on the coefficients and the feedback gains. The key idea of the proof is to combine the regularization techniques with the characteristics method. Furthermore, by the spectral analysis method, it is also shown that the closed loop system has a sequence of generalized eigenfunctions, which form a Riesz basis for the state space, and hence the spectrum-determined growth condition is deduced.

AB - This paper deals with the boundary feedback stabilization problem of a wide class of linear first order hyperbolic systems with non-smooth coefficients. We propose static boundary inputs (actuators) which lead us to a closed loop system with non-smooth coefficients and non-homogeneous boundary conditions. Then, we prove the exponential stability of the closed loop system under suitable conditions on the coefficients and the feedback gains. The key idea of the proof is to combine the regularization techniques with the characteristics method. Furthermore, by the spectral analysis method, it is also shown that the closed loop system has a sequence of generalized eigenfunctions, which form a Riesz basis for the state space, and hence the spectrum-determined growth condition is deduced.

KW - C-semigroup

KW - First order hyperbolic linear system

KW - L-coefficients

KW - Regularization method

KW - Riesz basis

KW - Stability

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DO - 10.1016/j.jde.2008.08.010

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JO - Journal of Differential Equations

JF - Journal of Differential Equations

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